Abstract: A field effect transistor includes a buried gate pattern that is electrically isolated by being surrounded by a tunneling insulating film. The field effect transistor also includes a channel region that is floated by source and drain regions, a gate insulating film, and the tunneling insulating film. The buried gate pattern and the tunneling insulating film extend into the source and drain regions. Thus, the field effect transistor efficiently stores charge carriers in the buried gate pattern and the floating channel region.

Abstract: Embodiments of the invention include a partially insulated field effect transistor and a method of fabricating the same. According to some embodiments, a semiconductor substrate is formed by sequentially stacking a bottom semiconductor layer, a sacrificial layer, and a top semiconductor layer. The sacrificial layer may be removed to form a buried gap region between the bottom semiconductor layer and the top semiconductor layer. Then, a transistor may be formed on the semiconductor substrate. The sacrificial layer may be a crystalline semiconductor formed by an epitaxial growth technology.

Abstract: In a method of manufacturing a semiconductor device including a planar type transistor and a fin type transistor, a substrate having a first region and a second region is partially to form an isolation trench defining an isolation region and an active region. An insulation layer liner is formed on sidewalls of the isolation trench in the first region and the second region. An isolation layer fills an inner portion of the isolation trench. The insulation layer liner is partially removed to expose an upper surface of the substrate in the gate region of the first region, and an upper surface and sidewalls of the substrate in the gate region of the second region. A gate oxide layer and a gate electrode are formed on the exposed substrate.

Abstract: In a flash memory device, which can maintain an enhanced electric field between a control gate and a storage node (floating gate) and has a reduced cell size, and a method of manufacturing the flash memory device, the flash memory device includes a semiconductor substrate having a pair of drain regions and a source region formed between the pair of drain regions, a pair of spacer-shaped control gates each formed on the semiconductor substrate between the source region and each of the drain regions, and a storage node formed in a region between the control gate and the semiconductor substrate. A bottom surface of each of the control gates includes a first region that overlaps with the semiconductor substrate and a second region that overlaps with the storage node. The pair of spacer-shaped control gates are substantially symmetrical with each other about the source region.

Abstract: A single transistor floating-body dynamic random access memory (DRAM) device includes a floating body located on a semiconductor substrate and a gate electrode located on the floating body, the floating body including an excess carrier storage region. The DRAM device further includes source and drain regions respectively located at both sides of the gate electrode, and leakage shielding patterns located between the floating body and the source and drain regions. Each of the source and drain regions contact the floating body, which may be positioned between the source and drain regions. The floating body may also laterally extend under the leakage shielding patterns, which may be arranged at outer sides of the gate electrode.

Abstract: A example embodiment may provide a memory device that may include an active pattern on a semiconductor substrate, a first charge trapping layer pattern on the active pattern, a first gate electrode on the first charge trapping layer pattern, a second charge trapping layer pattern on a sidewall of the active pattern in a first direction, a second gate electrode on the second charge trapping layer pattern in the first direction, and/or a source/drain region in the active pattern. The memory device may have improved integration by forming a plurality of charge trapping layer patterns on the same active pattern.

Abstract: In a method of manufacturing a semiconductor device, a preliminary active pattern including gate layers and channel layers is formed on a substrate. The gate layers and the channel layers are alternatively stacked. A hard mask is formed on the preliminary active pattern. The preliminary active pattern is partially etched using the hard mask as an etching mask to expose a surface of the substrate. The etched preliminary active pattern is trimmed to form an active channel pattern having a width less than a lower width of the hard mask. Source/drain layers are formed on exposed side faces of the active channel pattern and the surface. The gate layers are selectively etched to form tunnels. A gate encloses the active channel pattern and filling the tunnels. Related intermediate structures are also disclosed.

Abstract: A field effect transistor includes a buried gate pattern that is electrically isolated by being surrounded by a tunneling insulating film. The field effect transistor also includes a channel region that is floated by source and drain regions, a gate insulating film, and the tunneling insulating film. The buried gate pattern and the tunneling insulating film extend into the source and drain regions. Thus, the field effect transistor efficiently stores charge carriers in the buried gate pattern and the floating channel region.

Abstract: Embodiments of the invention include a partially insulated field effect transistor and a method of fabricating the same. According to some embodiments, a semiconductor substrate is formed by sequentially stacking a bottom semiconductor layer, a sacrificial layer, and a top semiconductor layer. The sacrificial layer may be removed to form a buried gap region between the bottom semiconductor layer and the top semiconductor layer. Then, a transistor may be formed on the semiconductor substrate. The sacrificial layer may be a crystalline semiconductor formed by an epitaxial growth technology.

Abstract: In a flash memory device, which can maintain an enhanced electric field between a control gate and a storage node (floating gate) and has a reduced cell size, and a method of manufacturing the flash memory device, the flash memory device includes a semiconductor substrate having a pair of drain regions and a source region formed between the pair of drain regions, a pair of spacer-shaped control gates each formed on the semiconductor substrate between the source region and each of the drain regions, and a storage node formed in a region between the control gate and the semiconductor substrate. A bottom surface of each of the control gates includes a first region that overlaps with the semiconductor substrate and a second region that overlaps with the storage node. The pair of spacer-shaped control gates are substantially symmetrical with each other about the source region.

Abstract: A fin field effect transistor (FinFET) includes a substrate, a fin, a gate electrode, a gate insulation layer, and source and drain regions in the fin. The fin is on and extends laterally along and vertically away from the substrate. The gate electrode covers sides and a top of a portion of the fin. The gate insulation layer is between the gate electrode and the fin. The source region and the drain region in the fin and adjacent to opposite sides of the gate electrode. The source region of the fin has a different width than the drain region of the fin.

Abstract: A semiconductor device having a field effect transistor and a method of forming the same are provided. The semiconductor device preferably includes a device active pattern disposed on a predetermined region of the substrate. The gate electrode preferably crosses over the device active pattern, interposed by a gate insulation layer. A support pattern is preferably interposed between the device active pattern and the substrate. The support pattern can be disposed under the gate electrode. A filling insulation pattern is preferably disposed between the device active pattern and the filling insulation pattern. The filling insulation pattern may be disposed under the source/drain region. A device active pattern under the gate electrode is preferably formed of a strained silicon having a lattice width wider than a silicon lattice.

Abstract: A method of forming a fin field effect transistor on a semiconductor substrate includes forming a fin-shaped active region vertically protruding from the substrate. An oxide layer is formed on a top surface and opposing sidewalls of the fin-shaped active region. An oxidation barrier layer is formed on the opposing sidewalls of the fin-shaped active region and is planarized to a height no greater than about a height of the oxide layer to form a fin structure. The fin structure is oxidized to form a capping oxide layer on the top surface of the fin-shaped active region and to form at least one curved sidewall portion proximate the top surface of the fin-shaped active region. The oxidation barrier layer has a height sufficient to reduce oxidation on the sidewalls of the fin-shaped active region about halfway between the top surface and a base of the fin-shaped active region. Related devices are also discussed.

Abstract: A semiconductor device employs an asymmetrical buried insulating layer, and a method of fabricating the same. The semiconductor device includes a lower semiconductor substrate. An upper silicon pattern is located on the lower semiconductor substrate. The upper silicon pattern includes a channel region, and a source region and a drain region spaced apart from each other by the channel region. A gate electrode is electrically insulated from the upper silicon pattern and intersects over the channel region. A bit line and a cell capacitor are electrically connected to the source region and the drain region, respectively. A buried insulating layer is interposed between the drain region and the lower semiconductor substrate. The buried insulating layer has an extension portion partially interposed between the channel region and the lower semiconductor substrate.

Abstract: In a method of manufacturing a semiconductor device, a preliminary active pattern including gate layers and channel layers is formed on a substrate. The gate layers and the channel layers are alternatively stacked. A hard mask is formed on the preliminary active pattern. The preliminary active pattern is partially etched using the hard mask as an etching mask to expose a surface of the substrate. The etched preliminary active pattern is trimmed to form an active channel pattern having a width less than a lower width of the hard mask. Source/drain layers are formed on exposed side faces of the active channel pattern and the surface. The gate layers are selectively etched to form tunnels. A gate encloses the active channel pattern and filling the tunnels. Related intermediate structures are also disclosed.

Abstract: A method of forming a fin field effect transistor on a semiconductor substrate includes forming a fin-shaped active region vertically protruding from the substrate. An oxide layer is formed on a top surface and opposing sidewalls of the fin-shaped active region. An oxidation barrier layer is formed on the opposing sidewalls of the fin-shaped active region and is planarized to a height no greater than about a height of the oxide layer to form a fin structure. The fin structure is oxidized to form a capping oxide layer on the top surface of the fin-shaped active region and to form at least one curved sidewall portion proximate the top surface of the fin-shaped active region. The oxidation barrier layer has a height sufficient to reduce oxidation on the sidewalls of the fin-shaped active region about halfway between the top surface and a base of the fin-shaped active region. Related devices are also discussed.

Abstract: An SOI substrate is fabricated by providing a substrate having a sacrificial layer thereon, an active semiconductor layer on the sacrificial layer remote from the substrate and a supporting layer that extends along at least two sides of the active semiconductor layer and the sacrificial layer and onto the substrate, and that exposes at least one side of the sacrificial layer. At least some of the sacrificial layer is etched through the at least one side thereof that is exposed by the supporting layer to form a void space between the substrate and the active semiconductor layer, such that the active semiconductor layer is supported in spaced-apart relation from the substrate by the supporting layer. The void space may be at least partially filled with an insulator lining.

Abstract: A semiconductor device may include a substrate and a fin shaped semiconductor region on the substrate. The fin shaped semiconductor region may include a channel region and first and second junction regions on opposite sides of the channel region. A gate electrode may be provided on the channel region of the fin shaped semiconductor region, and a stress inducing layer on the fin shaped semiconductor region.

Abstract: An SOI substrate is fabricated by providing a substrate having a sacrificial layer thereon, an active semiconductor layer on the sacrificial layer remote from the substrate and a supporting layer that extends along at least two sides of the active semiconductor layer and the sacrificial layer and onto the substrate, and that exposes at least one side of the sacrificial layer. At least some of the sacrificial layer is etched through the at least one side thereof that is exposed by the supporting layer to form a void space between the substrate and the active semiconductor layer, such that the active semiconductor layer is supported in spaced-apart relation from the substrate by the supporting layer. The void space may be at least partially filled with an insulator lining.

Abstract: According to some embodiments, a semiconductor device includes a lower semiconductor substrate, an upper silicon pattern, and a MOS transistor. The MOS transistor includes a body region formed within the upper silicon pattern and source/drain regions separated by the body region. A buried insulating layer is interposed between the lower semiconductor substrate and the upper silicon pattern. A through plug penetrates the buried insulating layer and electrically connects the body region with the lower semiconductor substrate, the through plug positioned closer to one of the source/drain regions than the other source/drain region. At least some portion of the upper surface of the through plug is positioned outside a depletion layer when a source voltage is applied to the one of the source/drain regions, and the upper surface of the through plug is positioned inside the depletion layer when a drain voltage is applied to the one region.